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Putting Competing Orders in their Place near the Mott Transition. Leon Balents (UCSB) Lorenz Bartosch (Yale) Anton Burkov (UCSB) Predrag Nikolic (Yale) Subir Sachdev (Yale) Krishnendu Sengupta (Toronto). cond-mat/0408329, cond-mat/0409470, and to appear. Mott Transition. localized, .
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Putting Competing Orders in their Place near the Mott Transition Leon Balents (UCSB) Lorenz Bartosch (Yale) Anton Burkov (UCSB) Predrag Nikolic (Yale) Subir Sachdev (Yale) Krishnendu Sengupta (Toronto) cond-mat/0408329, cond-mat/0409470, and to appear
Mott Transition localized, delocalized, • Many interesting systems near Mott transition • Cuprates • NaxCoO2¢ yH2O • Organics: -(ET)2X • LiV2O4 • Unusual behaviors of such materials • Power laws (transport, optics, NMR…) suggest QCP? • Anomalies nearby • Fluctuating/competing orders • Pseudogap • Heavy fermion behavior (LiV2O4) insulating (super)conducting
Theory of Mott transition must incorporate this constraint Competing Orders “Usually” Mott Insulator has spin and/or charge/orbital order (LSM/Oshikawa) Luttinger Theorem/Topological argument : some kind of order is necessary in a Mott insulator (gapped state) unless there is an even number of electrons per unit cell - Charge/spin/orbital order - In principle, topological order (not subject of talk)
The cuprate superconductor Ca2-xNaxCuO2Cl2 Multiple order parameters: superfluidity and density wave. Phases: Superconductors, Mott insulators, and/or supersolids T. Hanaguri, C. Lupien, Y. Kohsaka, D.-H. Lee, M. Azuma, M. Takano, H. Takagi, and J. C. Davis, Nature430, 1001 (2004).
Fluctuating Order in the Pseudo-Gap “density” (scalar) modulations, ≈ 4 lattice spacing period LDOS of Bi2Sr2CaCu2O8+d at 100 K.M. Vershinin, S. Misra, S. Ono, Y. Abe, Y. Ando, and A. Yazdani, Science, 303, 1995 (2004).
Landau-Ginzburg-Wilson (LGW) Theory • Landau expansion of effective action in “order parameters” describing broken symmetries • Conceptual flaw: need a “disordered” state • Mott state cannot be disordered • Expansion around metal problematic since large DOS means bad expansion and Fermi liquid locally stable • Physical problem: Mott physics (e.g. large U) is central effect, order in insulator is a consequence, not the reverse. • Pragmatic difficulty: too many different orders “seen” or proposed • How to choose? • If energetics separating these orders is so delicate, perhaps this is an indication that some description that subsumes them is needed (put chicken before the eggs)
What is Needed? • Approach should focus on Mott localization physics but still capture crucial order nearby • Challenge: Mott physics unrelated to symmetry • Not an LGW theory! • Insist upon continuous (2nd order) QCPs • Robustness: • 1st order transitions extraordinarily sensitive to disorder and demand fine-tuned energetics • Continuous QCPs have emergent universality • Want (ultimately – not today) to explain experimental power-laws
Bose Mott Transitions • This talk: Superfluid-Insulator QCPs of bosons on (square) 2d lattice (connection to electronic systems later) Filling f=1: Unique Mott state w/o order, and LGW works f 1: localized bosons must order M. Greiner, O. Mandel, T. Esslinger, T. W. Hänsch, and I. Bloch, Nature415, 39 (2002).
Is LGW all we know? • Physics of LGW formalism is particle condensation • Order parameter y creates particle (z=1) or particle/antiparticle superposition (z=2) with charge(s) that generate broken symmetry. • The y particles are the natural excitations of the disordered state • Tuning s||2 tunes the particle gap (» s1/2) to zero • Generally want critical Quantum Field Theory • Theory of “particles” (point excitations) with vanishing gap (at QCP) • Any particles will do!
Approach from the Insulator (f=1) Excitations: • The particle/hole theory is LGW theory! - But this is possible only for f=1
Approach from the Superfluid Focus on vortex excitations vortex anti-vortex • Time-reversal exchanges vortices+antivortices - Expect relativistic field theory for Worry: vortex is a non-local object, carrying superflow
Duality C. Dasgupta and B.I. Halperin, Phys. Rev. Lett. 47, 1556 (1981); D.R. Nelson, Phys. Rev. Lett. 60, 1973 (1988); M.P.A. Fisher and D.-H. Lee, Phys. Rev. B 39, 2756 (1989); Exact mapping from boson to vortex variables. Dual magnetic field B = 2n Vortex carries dual U(1) gauge charge All non-locality is accounted for by dual U(1) gauge force
N.B.: vortex field is not gauge invariant - not an order parameter in Landau sense Dual Theory of QCP for f=1 • Two completely equivalent descriptions - really one critical theory (fixed point) with 2 descriptions particles= bosons particles= vortices Mott insulator superfluid C. Dasgupta and B.I. Halperin, Phys. Rev. Lett. 47, 1556 (1981); Real significance: “Higgs” mass indicates Mott charge gap
Non-integer filling f 1 • Vortex approach now superior to Landau one • need not postulate unphysical disordered phase • Vortices experience average dual magnetic field - physics: phase winding Aharonov-Bohm phase 2 vortex winding
Vortex Degeneracy Non-interacting spectrum = Hofstadter problem Physics: magnetic space group For f=p/q (relatively prime) all representations are at least q-dimensional and This q-fold vortex degeneracy of vortex states is a robust property of a superfluid (a “quantum order”)
Nz=§ 1 A simple example: f=1/2 C. Lannert, M.P.A. Fisher, and T. Senthil, Phys. Rev. B 63, 134510 (2001) ; S. Sachdev and K. Park, Annals of Physics, 298, 58 (2002) • A simple physical interpretation is possible for f=1/2 • Map bosons to spins: spin-1/2 XY-symmetry magnet = = Suppose =Nx+iNy Order in core: 2 “merons” much more interpretation of this case: T. Senthil et al,Science 303, 1490 (2004).
Vortex PSG Representation of magnetic space group • Vortices carry space group and U(1) gauge charges - PSG ties together Mott physics (gauge) and order (space group) - condensation implies both Mott SF-I transition and spatial order
Order in the Mott Phase Gauge-invariant bilinears: Transform as Fourier components of density with • Vortex condensate always has some order - The order is a secondary consequence of Mott transition
Critical Theory and Order mn and H.O.T.s constrained by PSG • “Unified” competing orders determined by simple MFT • always integer number of bosons per enlarged unit cell Caveat: fluctuation effects mostly unknown f=1/4,3/4
“Deconfined” Criticality Under some circumstances, these QCPs have emergent extra U(1)q-1 symmetry f=1/2, 1/4 f 1/3 In these cases, there is a local, direct, formulation of the QCP in terms of fractional bosons interacting with q-1 U(1) gauge fields (with conserved gauge flux) charge 1/q bosons Can be constructed in detail directly, generalizing f=1/2 T. Senthil et al,Science 303, 1490 (2004).
Electronic Models • Need to model spins and electrons - Expect: bosonic results hold if electrons are strongly paired (BEC limit of SC) • General strategy: • Start with a formulation whose kinematical variables have “spin-charge separation”, i.e. bosonic holons and fermionic spinons - Apply dual analysis to holons N.B. This does not mean we need presume any exotic phases where these are deconfined, since gauge fluctuations are included. • Cuprates: model singlet formation • Doped dimer model • Doped staggered flux states (generally SU(2) MF states)
Singlet formation g spin liquid Valence bond solid (VBS) La2CuO4 x Staggered flux spin liquid • Model for doped VBS • doped quantum dimer model
i j Doped dimer model E. Fradkin and S. A. Kivelson, Mod. Phys. Lett. B 4, 225 (1990). Dimer model = U(1) gauge theory Holes carry staggered U(1) charge: hop only on same sublattice Dual analysis allows Mott states with x>0 x=0: 2 vortices = vortex in A/B sublattice holons
d-wave SC Doped dimer model: results dSC for x>xc with vortex PSG identical to boson model with pair density g x 1/8 1/32 1/16 xc
Application: Field-Induced Vortex in Superconductor • In low-field limit, can study quantum mechanics of a single vortex localized in lattice or by disorder - Pinning potential selects some preferred superposition of q vortex states locally near vortex Each pinned vortex in the superconductor has a halo of density wave order over a length scale ≈ the zero-point quantum motion of the vortex. This scale diverges upon approaching the insulator
7 pA 0 pA 100Å Vortex-induced LDOS of Bi2Sr2CaCu2O8+dintegrated from 1meV to 12meV at 4K Vortices have halos with LDOS modulations at a period ≈ 4 lattice spacings b J. HoffmanE. W. Hudson, K. M. Lang, V. Madhavan, S. H. Pan, H. Eisaki, S. Uchida, and J. C. Davis, Science 295, 466 (2002).
Doping Other Spin Liquids Very general construction of spin liquid states at x=0 from SU(2) MFT X.-G. Wen and P. A. Lee (1996) X.-G. Wen (2002) • Spinons fi described by mean-field hamiltonian + gauge fluctuations, dope b1,b2 bosons via duality - Doped dimer model equivalent to Wen’s “U1Cn00x” state with gapped spinons - Can similarly consider staggered flux spin liquid with critical magnetism preliminary results suggest continuous Mott transition into hole-ordered structure unlikely
Conclusions • Vortex field theory provides • formulation of Mott-driven superfluid-insulator QCP • consequent charge order in the Mott state • Vortex degeneracy (PSG) • a fundamental (?) property of SF/SC states • natural explanation for charge order near a pinned vortex • Extension to gapless states (superconductors, metals) to be determined